Cobalt-substituted horseradish peroxidase.

Horseradish peroxidase can be reconstituted with cobalt porphyrin to give a cobaltic holoenzyme having physicochemical properties quite similar to those of the native ferric protein. The cobaltic protein (Co3+HRP) can be reduced to the cobaltous form (CoHRP), the analogue of ferroperoxidase and the reduced cobalt protein can bind O2 to form an analogue of oxyferroperoxidase (Compound III). Since both the CoHRP and oxy-CoHRP are EPR-visible, the cobalt has been used to probe the nature of the heme crevice in these two protein forms. The occurrence of a three-line 14N superhyperfine pattern in the spectrum of the former unambiguously shows that in the divalent state of the protein the proximal axial ligand is a nitrogenous base. The spectrum of the latter shows a uniquely large Aparallel(59Co) = 23.2 G. Although we confirm the reported failure of the Co3+HRP to catalyze peroxide-dependent oxidations of classical peroxidase substrates (Gjessing, E.C., and Sumner, J.B. (1942) Arch. Biochem. 1, 1), the oxy-CoHRP does undergo oxidation-reduction reactions analogous to those exhibited in the cytochrome P-450 catalytic cycle.     

A possible difference in the heterogeneity of the heavy and light chains from a rabbit anti-p-azobenzoate antibody preparation.

CNBr cleavage of rabbit heavy (H) chains leads to the formation of a fragment, C-1, which consists of the N-terminal half of the H chain. Fragment C-1 is cleaved at methionyl residues but held together by intrachain S-S bonds so that smaller fragments can be liberated by total reduction and alkylation. In the case of the C-1 fragment from an anti-p-azobenzoate antibody preparation, which has a light (L) chain of markedly restricted heterogeneity, total reduction and alkylation liberated seven major fragments in good yield. The N-terminus of two of these fragments corresponds to position 35 of the H chain but their N-terminal sequences are clearly different. The H chain regions represented by the other fragments implied that they were derived from H chains having different distributions of methionyl residues. This hypothesis was supported by isolating six different antibody components from the antibody preparation by isoelectric focusing and then digesting them with CNBr. Comparison of the products showed that the six components all appeared to behave differently. These results are interpreted as suggesting that the process whereby H and L chains are paired in vivo may not be completely specific and may provide a simple means of generating a significant contribution to antibody diversity.     

Decreased binding of cytotoxic antibody by developing Schistosoma mansoni. Evidence for a surface change independent of host antigen adsorption and membrane turnover.

Schistosoma mansoni schistosomula maintained in chemically defined culture media became increasingly resistant to the cytotoxic effects of infected guinea pig serum. Two- and 6-day-old schistosomula recovered from mice showed no uptake of IgG antibody from infected guinea pig serum, as revealed by the indirect fluorescent antibody test. Results from this test remained negative when the schistosomula were tested at 0 C, after exposure to drugs which inhibit synthetic and secretory processes, or after being killed by heat or formalin. In contrast, new schistosomula collected within 3 hr after skin penetration bound IgG from infection serum under all test conditions, and showed increased susceptibility to cytotoxicity after exposure to various drugs. It thus appears that soon after skin penetration schistosomula undergo surface changes which prevent binding of antibody from infection serum. These changes can apparently take place in the absence of host antigens, and once they have occurred, do not depend on worm physiological processes for their function.     

Effect of metabolites and phosphorylase on the D to I conversion of glycogen synthase from human polymorphonuclear leukocytes.

The D to I conversion of glycogen synthase from human polymorphonuclear leukocytes was examined both in a gel-filtered homogenate and in a preparation of glycogen particles with adhering enzymes, purified by chromatography on concanavalin A bound to Sepharose. It was found that glucose 6-phosphate as well as mannose 6-phosphate, glucosamine 6-phosphate, and 2-deoxy-glucose 6-phosphate activated the reaction, whereas the corresponding sugars were without effect. Mn2+ and Ca2+ increased the conversion rate by 51% and 27%, respectively, whereas Mg2+ and inorganic phosphate were without effect. Sodium fluoride inhibited the reaction completely. Glycogen inhibited the reaction in physiological concentrations and 0.5 mM glucose 6-phosphate was able to overcome this inhibition. MgATP greatly augmented the inhibition caused by glycogen in the glycogen particle preparation. This combined effect could be overcome by glucose 6-phosphate in concentrations from 0.1 to 1 mM. Phosphorylase alpha purified from human polymorphonuclear leukocytes inhibited the D to I conversion in a glycogen particle preparation. The inhibition was counteracted by glucose 6-phosphate and to a lesser degree by AMP. Phosphorylase beta was also inhibitory, but only at higher concentrations than phosphorylase alpha. No phosphorylase phosphatase activity was found in the glycogen particle preparation, which may indicate that chromatography on concanavalin A-Sepharose separates this enzyme from the synthase phosphatase or partially destroys the activity of a hypothetical common protein phosphatase.     

Identification of the primary lesion in a protoporphyrin accumulating mutant of Chlamydomonas reinhardtii

Summary A group of chlorophyll deficient mutants (br _s mutants) of Chlamydomonas accumulates protoporphyrin and has poorly developed chloroplast membrane systems (Wang et al. 1974). In order to determine whether a poorly developed chloroplast membrane system is the reason for, or the result of, the inability of the br _s mutants to metabolize protoporphyrin to chlorophyll, a second mutation was selected which restored chlorophyll synthesis in br _s mutants. One such double mutant (br _s-2 g-4) was analyzed. The double mutant br _s-2 g-4 has partially restored chlorophyll synthesis, but has defective photosystem II and photosystem I electron transport as well as abnormal chloroplast ultrastructure. Since these defects are not present in cells carrying only the g-4 mutation, they are presumed to be caused by the br _s-2 mutation. It is concluded that a defect in chloroplast membrane development resulting from the br _s-2 mutation causes an apparent defect in magnesium chelation by protoprophyrin. This is consistant with evidence that chlorophyll biosynthesis from magnesium protoporphyrin to chlorophyll takes place on the chloroplast membranes.     

Electrostatic components of drug-receptor recognition. I. Structural and sequence analogues of DNA polynucleotides

The electrostatic fields associated with the important biological receptor DNA have been studied by means of stereoscopic displays to investigate drug-receptor recognition processes. This revealed great differences between A- and B-type structures and enabled significant nucleotide sequence effects to be detected for the latter helix. These variations were further investigated by topological analysis of the surface potential in the two grooves of the B-DNA duplex at different radii from the helix axis. This made it possible to characterize the potential surface and to allocate curvature changes to specific atomic groupings. A general finding was that larger potential fields were found in the space encompassed by the narrow groove with strong potential gradients from the ends of the helix to the centre in both grooves. This gradient may provide a motive force for translating small molecules on the surface of a polynucleotide.     

Microbial cooxidation of naphthalene for the production of 1,2-dihydroxy-1,2-dihydronaphthalene

A microbial cooxidation process for 1,2-dihydroxy-1,2-dihydronaphthalene from naphthalene has been demonstrated. A Pseudomonas putida it119 mutant strain grown with glucose as the sole carbon and energy source was used to oxidize naphthalene. Growth characteristics of the P. putida mutant strain were studied in both batch and continuous fermentation experiments. The rate of product formation was found to depend on naphthalene particle sizes, initial naphthalene and glucose concentrations. Kinetic models were developed to quantify the microbial cooxidation process and a two-stage fermentation process is proposed for further studies.